Nature of the antigenic complex recognized by T lymphocytes. IV. Inhibition of antigen-specific T cell proliferation by antibodies to stimulator macrophage Ia antigens.

We have previously demonstrated that nonimmune guinea pig T lymphocytes could be specifically sensitized with TNP-modified allogeneic macrophages after eliminating the alloreactive T cells with bromodeoxyuridine (BUdR) and light treatment. This procedure allowed the unique opportunity to use anti-Ia sera directed against the Ia antigens of only the stimulator macrophages or responder T cells to determine against which cell type anti-Ia would block TNP-specific stimulation. It was found that the TNP-specific DNA synthetic response of BUdR and light-treated T cells stimulated with TNP-modified allogeneic macrophages was totally eliminated by anti-Ia sera directed solely against the allogeneic stimulator macrophage. In contrast, anti-Ia sera directed only against the responder T cells had no effect on their response to TNP-modified allogeneic macrophages. These findings indicate that macrophage Ia antigens are required for efficient T cell-macrophage interactions and raise the possibility that T cell Ia antigens may not be required for collaboration with macrophages. This latter possibility was substantiated by experiments in which we show that treating T cells with anti-Ia sera and complement to remove the Ia-positive cells either before or after priming, or both, had no effect on their ability to be primed and restimulated with TNP-modified macrophages.     

The requirement of viable thymocytes for species-specific attachment to and release from macrophages.

The role of the thymocyte in its species-specific binding to macrophages has been explored. Although formalin treatment of macrophages resulted in loss of binding to thymocytes, formalin treatment of thymocytes did not have this effect. However, two differences between living and formalin-treated thymocytes were noted. Formalin-treated thymocytes bound to macrophages of any species whereas the binding of living thymocytes was species specific. Living thymocytes attained maximum binding in approximately 1 hr and then the fraction bound gradually diminished. Formalin-treated thymocytes remained bound to the macrophage and appeared to be phagocytized. Released thymocytes did not bind to fresh macrophages, but released macrophages bound to fresh thymocytes. The results suggest that the binding of thymocytes to macrophages results in maturation of thymocytes.     

Nature of the antigenic complex recognized by T lymphocytes. VII. Evidence for an association between TNP-conjugated macrophage membrane components and Ia antigens.

In the present study we examined the effects of anti-sera directed against guinea pig Ia antigens on the ability of TNP-conjugated macrophages to stimulate TNP-specific T lymphocyte proliferation. Treatment of macrophages with anti-Ia sera for 1 hr before, 1 hr immediately after, or as late as 24 hr after TNP-modification resulted in a reduced ability to stimulate the TNP-specific T cell. The inhibition produced by anti-Ia sera was specific and did not result from interference with the ability of macrophages to process TNP-conjugated membrane antigens in a nonspecific manner. Brief treatment with anti-Ia serum did not result in inhibition of Ia-antigen synthesis nor could evidence of carry-over of anti-Ia antibody into the lymphocyte cultures be obtained. These results demonstrate that anti-Ia sera interfere with the development of a TNP-specific immunogen on the macrophage surface and strongly suggest that an association exists between TNP-modified membrane proteins and Ia antigens on the macrophage surface.     

Ia-positive macrophages bind and internalize viable lymphocytes in murine thymus

Macrophages have been shown to be present in thymus throughout its development. In the present study monoclonal and polyclonal antimacrophage reagents were used to identify, quantitate, and determine the distribution of thymic macrophages. Those studies demonstrated that significant numbers of macrophages were evenly distributed throughout the cortex and medulla, and that macrophages account for most, if not all, Ia positivity in murine thymus. Suspensions of thymic cells prepared by enzyme digestion contained 2-4% macrophage antigen-positive cells, over 95% of which were I-Ak positive in double-labeling studies. Removal of lymphocytes and macrophages left only epithelial cells and those failed to label for Ia. Subsequent to mild enzymatic digestion, up to 80% of the thymic macrophages were in the form of lymphocyte/macrophage rosettes. Morphologic evaluation of the thymocyte rosettes revealed that some of the macrophages contained internalized lymphocytes. The proportion of macrophages with internalized lymphocytes generally was less than 10%, but during the first 4 weeks of life values often approached 30%. Nurse cells, which were shown through double labeling to express both Ia and macrophage-associated antigen, were included in the population of rosetted cells which had internalized lymphocytes. The results demonstrated that there is a high level of interaction between lymphocytes and Ia-positive macrophages in the thymus which is greatest during the immediate postnatal period.     

Thymocyte and macrophage interactions: separation of murine thymocyte subsets and enrichment of syngeneic cell-responding thymocytes by adsorption to macrophage monolayers

The spontaneous binding of murine thymocytes to macrophage monolayers was employed to separate thymocytes into macrophage-unbound and -bound subsets, and the functional reactivities of these two subpopulations were examined. Macrophage-unbound thymocytes were found to be enriched in functional subsets reactive to semi-allogeneic and allogeneic stimulating spleen cells by proliferation in mixed leukocyte culture (MLC). Furthermore, macrophage-unbound thymocytes were frequently found to respond to syngeneic spleen cells. This syngeneic proliferative response showed both memory and specificity upon subsequent restimulation and thus seems to represent a syngeneic mixed leukocyte reaction (SMLR). Syngeneic responding thymocytes were also found to produce interleukin 2 when cultured with syngeneic but not allogeneic stimulator cells. In contrast, macrophage-bound thymocytes showed greatly reduced proliferative responses to allogeneic stimulators and no responses to syngeneic stimulators. The macrophage-bound thymocyte subset was not enriched in detectable suppressive activity; proliferative responses of macrophage-unbound thymocytes to either allogeneic or syngeneic cells were neither suppressed nor enhanced when macrophage-unbound thymocytes were added to the cultures. Thus, the macrophage-unbound subset seems to be enriched in functionally mature thymocytes and the macrophage-bound subset appears to be enriched in functionally immature thymocytes. This functional separation of thymocytes by macrophage adherence also correlated well with thymocyte subpopulations separated by bovine serum albumin density gradients; the low density mature thymocytes showed enhanced responses to both allogeneic and syngeneic stimulators, whereas the high density immature cells were unresponsive. This correlation was supported further by binding studies in which T cell tumor lines derived from C57BL/6 mice were used. ERLD tumor cells, which are similar to cortical immature thymocytes in both enzymatic and surface antigenic markers, were found to bind readily to macrophages, whereas both EL-4 and E male G2 tumor cells, with characteristics of mature thymocytes, bound to macrophages poorly. The binding of thymocytes and ERLD tumor cells to macrophages was not genetically restricted. We speculate that thymocyte binding to macrophages may play a critical role during the functional maturation of thymocytes.     

Specific binding of T lymphocytes to macrophages. V. The role of Ia antigens on Mphi in the binding.

The effect of anti-Ia alloantiserum on the capacity of selected peritoneal exudate lymphocytes (selected PEL) to bind to antigen-pulsed F1 (responder x nonresponder) macrophages was investigated. With the use of selected PEL for antigens under Ir gene control, it was shown that anti-Ia serum to the responder haplotype blocked adherence of selected PEL to antigen-pulsed macrophages whereas anti-Ia serum to the nonresponder haplotype did not. The target cell of the anti-Ia alloantiserum appeared to be the macrophage because anti-13 Ia in contrast to anti-2 Ia did not inhibit binding of F1 (2 x 13) DNP-GL selected PEL to DNP-GL pulsed strain-2 Mphi (responder strain). Taken together with previous experiments that indicate that an antibody to the native protein antigen employed is unable to block specific binding, the present results suggest that T cells may recognize fragments of exogenous antigen in association with Ia molecules.     

A novel guinea pig macrophage-specific polymorphic molecule. I. Biochemistry, genetics, and tissue distribution

In the course of studying Ia molecules from strain 2 and strain 13 guinea pig macrophages, with the intent of comparing them to B cell Ia molecules, it was observed that guinea pig alloserum prepared by cross-immunization of guinea pig lymphocyte Ag non-identical inbred guinea pigs immunoprecipitated not only conventional class I and class II molecules, but also a 98,000-Da molecule, termed gp98. Two different forms of the molecule were detected, indicating it is polymorphic. The genes encoding gp98 were shown not to be linked to the guinea pig lymphocyte Ag complex. The molecule gp98 was found on macrophages within populations of peritoneal exudate cells, resident peritoneal cells, bone marrow cells, and spleen. All gp98-bearing macrophages were also Ia-positive. However, only a subpopulation of macrophages bore gp98. The gp98 was not found on Ly-1 or Ig-bearing cells, indicating that B and T cells do not bear Ia. Thus, gp98 appears to be a highly immunogenic polymorphic macrophage-specific molecule that allows the characterization of guinea pig macrophage subsets.     

Effect of interferon-gamma and human alpha 2-macroglobulin on peritoneal macrophage morphology and Ia antigen expression.

While the primary role of the plasma protein alpha 2-macroglobulin (alpha 2M) appears to be related to its proteinase inhibitory activity, alpha 2M has been reported to regulate the immune response in vitro. Previous studies have demonstrated that, although native alpha 2M has no effect on macrophage function, proteinase- or CH3NH2-treated alpha 2M antagonize the IFN-gamma-induced expression of class II major histocompatibility complex (Ia) antigens on mouse peritoneal macrophages. In this investigation, we examined the effects of alpha 2M-CH3NH2 on the IFN-gamma-induced expression of macrophage Ia antigens by indirect immunofluorescence microscopy, radioimmunoassay, and immunoprecipitation of biosynthetically-labelled Ia. While alpha 2M-CH3NH2 suppressed the IFN-gamma induced increase in the percentage of Ia-positive macrophages detected by immunofluorescence microscopy, alpha 2M-CH3NH2 had no effect on the average of number of Ia molecules expressed per cell as detected by radioimmunoassay. In addition, alpha 2M-CH3NH2 had no effect on the ability of IFN-gamma to induce biosynthesis of Ia. Microscopic examination of IFN-gamma-treated macrophages revealed that treatment with alpha 2M-CH3NH2 prevented IFN-gamma-induced changes in macrophage morphology. IFN-gamma-treatment of elongated inflammatory macrophages was associated with the generation of round cells which possessed few cytoplasmic projections. By contrast, addition of alpha 2M-CH3NH2 to the incubation prevented the IFN-gamma-induced morphological changes, and the cells remained elongated with irregular cytoplasmic borders. We postulate that alpha 2M-CH3NH2 decreases the IFN-gamma-induced expression of Ia by preventing morphological changes in macrophages, resulting in the distribution of existing Ia over a larger surface area. As a consequence of this, the perceived fluorescence intensity of the bound antibody is lowered and the cells appear to be Ia-negative.     

The requirement of Ia-positive accessory cells for the induction of tumor-specific cytotoxic T lymphocytes in vitro

The mechanism for the induction of cytotoxic T cells specific for tumor-associated antigens was studied by using fractionated responder T cells, tumor cells, and accessory cells in vitro. The tumor-specific cytotoxic T cells were induced by culturing immunized spleen cells with the tumor cells in vitro for 5 days. Nylon-column-purified T cells alone did not induce cytotoxic T cells upon culture with tumor cells, but the addition of normal spleen cells as accessory cells did successfully induce the cytotoxic T cells, suggesting that the presence of accessory cells is required for the activation of tumor-specific cytotoxic T cells in vitro. The accessory function was associated with spleen cell populations adhering to a plastic dish, a Sephadex G-10 column or a nylon wool column, and was sensitive to anti-Ia serum and C treatment, but was resistant to anti-Ig serum or anti-Thy 1 serum and C treatment, suggesting that the accessory cells are Ia-positive macrophages. Not only syngeneic but also allogeneic macrophages had the accessory function and the allogeneic macrophages were also Ia positive. These results suggest that Ia-positive macrophages play a crucial role in the induction of tumor-specific cytotoxic T cells in vitro. The possible role of Ia-positive accessory cells in the induction of tumor-specific cytotoxic T cells is discussed from the standpoint of cellular interactions.     

The expression of Ia antigenic determinants on macrophages required for the in vitro antibody response.

A subpopulation of antigen-presenting macrophages required for an in vitro antibody response to burro erythrocytes was deleted by pretreating the splenic macrophages with anti-Ia serum and complement (C). The in vitro response of the macrophage depleted T-B cell population could not be restored by the addition of macrophages resistant to anti-Ia antibodies and C (Ia-). The response of Ia- macrophages and the macrophage-depleted T-B cells was only reconstituted by the addition of Ia+ macrophages. Macrophages pretreated with anti-Ia antibodies restricted to react with determinants of one I subregion could not support the in vitro antibody response when added to cultures whose macrophages were pretreated with anti-Ia serum and C specific for the I-J subregion. These results confirmed that Ia determinants of the I-A, the I-E, and the I-C subregions were all expressed on the I-J+ macrophage required for an in vitro antibody response.     

Antigen-binding receptors on T cells from long-term MLR. Evidence of binding sites for allogeneic and self-MHC products

Antibody inhibition of radiolabelled stimulator membrane vesicle binding by T blasts activated in the mixed lymphocyte reaction (MLR) was used to identify responder-cell determinants involved in the binding phenomenon. Antisera or monoclonal antibodies against Thy-1, Lyt-1, Lyt-2 and Ly-6 antigens were not inhibitory. However, antibodies against heavy-chain V region (V_H) determinants strongly inhibited vesicle binding by both primary and longterm MLR blasts. Anti-Ia (both alloantisera and monoclonal reagents) caused inhibition of antigen binding by primary MLR blasts only. T blasts from long-term MLR lines were neither Ia-positive, nor susceptible to blocking of antigen binding with anti-Ia. However, these cells were capable of specifically absorbing soluble syngeneic Ia material, with the concomitant appearance of vesiclebinding inhibition with anti-Ia sera. Acquisition of syngeneic Ia by T blasts was effectively blocked with the anti-V_H reagent. Passively bound self-Ia did not interfere with vesicle binding in the absence of anti-Ia. These results strongly suggest the existance of specific self-Ia acceptor sites closely linked to the receptors for stimulator alloantigens on T cells proliferating in MLR. A receptor model based on these findings is briefly discussed.Abbreviations used in this paper B10 C57BL/10 - Con A concanavalin A - FcR Fc receptor - FCS fetal calf serum - H heavy chain - Ia I-region associated antigen - Ig immunoglobulin - LPS lipopolysaccharide - Lyt T-lymphocyte differentiation antigen - MHC major histocompatibility complex - MLR mixed lymphocyte reaction - PM plasma membrane - T thymus derived - Tcr T-cell receptor - V variable region of Ig     

Antigen-binding receptors on T cells from long-term MLR. evidence of binding sites for allogeneic and self-MHC products

Antibody inhibition of radiolabelled stimulator membrane vesicle binding by T blasts activated in the mixed lymphocyte reaction (MLR) was used to identify responder-cell determinants involved in the binding phenomenon. Antisera or monoclonal antibodies against Thy-1, Lyt-1, Lyt-2 and Ly-6 antigens were not inhibitory. However, antibodies against heavy-chain V region (VH) determinants strongly inhibited vesicle binding by both primary and long-term MLR blasts. Anti-Ia (both alloantisera and monoclonal reagents) caused inhibition of antigen binding by primary MLR blasts only. T blasts from long-term MLR lines were neither Ia-positive, nor susceptible to blocking of antigen binding with anti-Ia. However, these cells were capable of specifically absorbing soluble syngeneic Ia material, with the concomitant appearance of vesicle-binding inhibition with anti-Ia sera. Acquisition of syngeneic Ia by T blasts was effectivelly blocked with the anti-VH reagent. Passively bound self-Ia did not interfere with vesicle binding in the absence of anti-Ia. These results strongly suggest the existance of specific self-Ia acceptor sites closely linked to the receptors for stimulator alloantigens on T cells proliferating in MLR. A receptor model based on these findings is briefly discussed.     

Arachidonic acid accumulates in the stromal macrophages during thymus involution in diabetes

Diabetes is a debilitating disease with chronic evolution that affects many tissues and organs over its course. Thymus is an organ that is affected early after the onset of diabetes, gradually involuting until it loses most of its thymocyte populations. We show evidence of accumulating free fatty acids with generation of eicosanoids in the diabetic thymus and we present a possible mechanism for the involution of the organ during the disease. Young rats were injected with streptozotocin and their thymuses examined for cell death by flow cytometry and TUNEL reaction. Accumulation of lipids in the diabetic thymus was investigated by histology and electron microscopy. The identity and quantitation of accumulating lipids was done with gas chromatography-mass spectrometry and liquid chromatography. The expression and dynamics of the enzymes were monitored via immunohistochemistry. Diabetes causes thymus involution by elevating the thymocyte apoptosis. Exposure of thymocytes to elevated concentration of glucose causes apoptosis. After the onset of diabetes, there is a gradual accumulation of free fatty acids in the stromal macrophages including arachidonic acid, the substrate for eicosanoids. The eicosanoids do not cause thymocyte apoptosis but administration of a cyclooxygenase inhibitor reduces the staining for ED1, a macrophage marker whose intensity correlates with phagocytic activity. Diabetes causes thymus involution that is accompanied by accumulation of free fatty acids in the thymic macrophages. Excess glucose is able to induce thymocyte apoptosis but eicosanoids are involved in the chemoattraction of macrophage to remove the dead thymocytes.     

Accessory cell function in the Con A response: role of Ia-positive and Ia-negative accessory cells

We have examined the role of Ia-positive and Ia-negative accessory cells (AC) and soluble factors in Con A-stimulated murine T cell activation. Supernatant fluids containing interleukin 1 (IL 1) derived from the P388D1 macrophage cell line and from a lipopolysaccharide (LPS)-stimulated macrophage hybridoma provided only partial reconstitution of the response of purified T cells (18 to 27%). The complete reconstitution obtained with gamma-irradiated spleen cells or LPS-activated B cells was inhibited by approximately 60 to 77% when anti-Ia antibody was included in the culture. Despite this apparent involvement of Ia+ spleen AC, Ia-negative L cell AC could also reconstitute the response of both Class I-restricted Lyt-2+ T cells and Class II-restricted L3T4+ T cells. When the Ia-negative AC were employed, the L3T4 antigen on L3T4+ T cells played a critical role because addition of anti-L3T4 antibody to the culture inhibited the response by 85 to 90%. In contrast, anti-L3T4 did not inhibit the response in the presence of spleen AC. These results suggest that the molecules involved in T cell-AC interactions may vary depending on the AC source. Moreover, at least one of the putative target ligands for L3T4 presumably is not Ia, because anti-L3T4 inhibited T cell stimulation when Ia-negative AC were used.     

Correlation between increase in Ia-bearing macrophages and induction of T cell-dependent antitumor activity by Lactobacillus casei in mice

Summary When Lactobacillus casei YIT 9018 (LC 9018) or Corynebacterium parvum, known to be immunomodulators possessing antitumor activity, were injected i.p. into BALB/c mice, peritoneal exudate macrophage Ia antigen detected by indirect immunofluorescence method was expressed on their cell surface, but it was not expressed following the injection of 10% proteose peptone, an inflammatory agent, or Lactobacillus fermentum YIT 0159 (LF 0159), which have no antitumor activity. The percentage and absolute number of Ia-positive peritoneal macrophages were maximum on the 7th day after the injection of LC 9018. Immunization by injection of Meth A fibrosarcoma cells treated with mitomycin C (MMC-Meth A) 7 days after LC 9018 injection suppressed the growth of Meth A implanted i.p. 14 days after MMC-Meth A injection. A shorter interval between the injections of LC 9018 and MMC-Meth A did not allow suppression of Meth A growth. These results showed that the increase in Ia-positive macrophages in the peritoneal cavity coincided with the effective interval for induction of the antitumor activity by LC 9018. The antitumor activity induced by injections of LC 9018 and MMC-Meth A did not affect the growth of RL l leukemic cells, syngeneic to BALB/c mice. Neutralization (Winn type) tests showed that peritoneal T lymphocytes possessed tumor cytotoxicity and that the antitumor capacity was reduced by in vivo treatment with anti I-A^d monoclonal antibody simultaneously with and 1 day prior to MMC-Meth A injection. These results indicate that LC 9018-induced Ia-positive macrophages, which first encounter a tumor antigen in the peritoneal cavity, play an important role in the in vivo induction of tumor specific T cell-mediated antitumor immunity.     

The role of Ia antigens and Fc receptor-bearing T-cells in the inhibition of macrophage receptors for cytophilic antibody induced by soluble immune complexes

Soluble antigen-antibody complexes composed of 3 M KCl-extracted L1210 antigens and alloantibody to L1210 given to C3H mice caused immunosuppression in the mice. This was reflected in part by the inhibition of cytophilic antibody receptors on macrophages which could be used as a measure of the suppression. Thymocytes or splenic T cells from mice treated with immune complexes could adoptively transfer the suppression to normal syngeneic mice. These cells, which we have termed suppressor inducers, were found to be Ia positive: specifically, I-A⁺, I-J^?. Thus, treatment of the inducers with anti-la or anti-I-A antibodies and complement in vitro abrogated their ability to transfer the suppression to normal mice. In contrast treatment with anti-I-J serum and complement had no effect. Through a similar approach, the cooperating (acceptor) T cells were found to be I-A⁺, I-J^?. Pretreatment of mice with anti-Ia or anti-I-A serum before the administration of antigen-antibody complexes prevented the inhibition of macrophages. This was due at least in part to steric hindrance of adjacent Fc receptors on the FcR⁺ T cells with which the complexes interacted. Early interaction of immune complexes with FcR⁺ T cells was in fact demonstrated directly by the inability of the complexes to induce suppression when FcR⁺ T cells were depleted. The thymocytes or splenic T cells from anti-Ia-pretreated mice failed to transfer the suppression to recipient mice. In contrast, treatment with either anti-Ia or anti-I-A after the immune complexes did not abrogate the generation of suppressor inducers. Treatment of normal recipient mice with anti-Ia serum in vivo before they received the suppressor inducer cells did not prevent cooperation between the two types of cells. By the same token, blocking of Ia antigens of the inducers in vitro with anti-Ia serum (without complement) also did not impair the cooperative interaction. These results indicate that antigen-antibody complexes generate I-A-positive, I-J-negative T-suppressor inducer cells from FcR⁺ naive T cells. These in turn interact with Ia-positive (I-A⁺ and I-J^?) normal thymocytes or spleen T cells. This interaction most likely generates the ultimate suppressor T cells that suppress cytophilic antibody receptors on macrophages in vivo. However, the I-region determined antigens did not appear to be directly involved in the T-T interaction of suppressor inducer and acceptor cells.     

Ontogeny of macrophage subpopulations and Ia-positive dendritic cells in pulmonary tissue of the rat

Summary The development of macrophage subpopulations and dendritic cells in the rat lung was studied from day 15 of gestation until day 21 after birth by means of immunohistochemical techniques combined with acid phosphatase staining. To characterize these cell populations, monoclonal antibodies raised against rat macrophage subpopulations were used (ED1, ED2, ED7, and ED8) in addition to anti-Ia antibodies. Ia-positive cells with a dendritic morphology were found on day 16 of gestation. During ontogeny, the number of these cells gradually increased. They were always found in mesenchymal lung tissue between the epithelial tubules of future alveoli, and in perivascular or peribronchial areas. ED1-positive macrophages were found on day 17 of gestation, with a distribution different from that of Ia-positive dendritic cells. The distribution of ED1-positive cells changed during ontogeny: before birth, ED1-positive cells were present in mesenchymal areas of lung tissue, whereas after the first week of postnatal life ED1 recognized all free alveolar macrophages. No Ia-expression was found on free alveolar macrophages. This developmental pattern resembles the ontogeny of Ia-positive dendritic cells and ED1-positive macrophages in gutassociated tissue. The comparable development of these cell populations in gut and lung tissue indicates a common ontogeny in the mucosal immune system.Fellow of the Royal Netherlands Academy of Arts and Sciences     

The specificity of delayed hypersensitivity to ABA-tyr-pulsed and ABA-coupled macrophages

Guinea pigs immunized with ABA-tyr in CFA respond well by skin test to ABA-tyr-pulsed macrophages but poorly to ABA-coupled macrophages and not at all to ABA-coupled red cells, thymocytes, or L₂C cells. On the other hand, guinea pigs immunized with ABA-coupled macrophages do not respond to ABA-insulin or ABA-tyr-pulsed macrophages but do respond to ABA-coupled macrophages. Similarly guinea pigs immunized with Ars-NCS-coupled macrophages respond only to the homologous antigen. The specificity of these reactions is determined by how ABA is associated with the Ia-positive accessory cell. The presence of Ia molecule is not a sufficient condition since neither Ia-positive L₂C cells nor spleen cells depleted of adherent macrophages are effective as immunogens or elicitors of response when coupled with ABA. These results suggest that the topography of the ABA and Ia complex formed on the accessory cell is the prime determinant of specificity for T-cells responses.     

Regulation of macrophage populations. I. Preferential induction of Ia-rich peritoneal exudates by immunologic stimuli

The amounts of Ia-positive and -negative macrophages were studied in peritoneal exudates of normal mice or of mice injected with various inflammatory materials, infected with Listeria monocytogenes, or injected with hemocyanin. Ia-negative macrophages predominated in exudates from normal mice or from mice given mineral oil, peptone, thioglycollate, culture media, or endotoxin. Infection with Listeria caused a very marked increase in Ia-positive macrophages. The induction of Ia-positive macrophages by Listeria inoculation resulted in great part from an immune process. The Ia-positive exudates were more readily generated in immune mice given a secondary challenge with heat-killed organisms. Furthermore, immune T cells transplanted together with heat-killed organisms into normal mice resulted in Ia-rich exudates. Injection of hemocyanin also induced Ia-rich exudates involving an immune process. We conclude that an immune reaction involving T cells regulates the Ia phenotype of the exudate macrophage population. The Ia-positive macrophages were Fc and C3 receptor positive and phagocytized latex particles.     

Identification of a macrophage-specific cell surface antigen.

A mouse-specific macrophage antigen (MSMA) was identified in NP-40 extracts of 125I-radiolabeled mouse preitoneal macrophages by using a rabbit anti-mouse macrophage serum (AMS) and SDS-polyacrylamide gel electrophoresis. The antigen was shown to have a m.w. of 83,000 daltons and was present on both normal and "activated" peritoneal macrophages. MSMA was also present on syngeneic adherent spleen cells, allogeneic peritoneal macrophages, a mouse macrophage cell line (P388D1), and exhibited some cross-reactivity with peritoneal macrophages from closely related species (rats and hamsters). MSMA was not present on nonadherent peritoneal exudate cells, spleen cells, erythrocytes, thymocytes, or bone marrow cells. Extensive absorptions of AMS with thymocytes and erytrocytes from mice were necessary to remove other antibodies that reacted with other mouse membrane antigens. An antiserum directed against a specific membrane antigen has great potential in elucidating structure-function relationships with regard to a number of macrophage activities.